DE527554C - Synchronous telegraph receiver for positive and negative direct current pulses, in which pulses of unit duration and of changing polarity are generated locally by means of a pulse relay to restore during the transmission of excessively damped pulses - Google Patents

Description

Synchronous telegraph receiver for positive and negative direct current pulses, in which to restore too much damped impulses during transmission Pulses of unit duration and of alternating polarity locally by means of pulse relays The invention relates to synchronously operating high-speed telegraph systems, in which short bursts of signal currents are very strongly attenuated and in the receiving station need to be rebuilt or regenerated.

The main purpose of the invention is that for the reconstruction of the short To simplify the device in the receiving station serving for signal current surges and to increase the reliability of the same.

In a telegraph system, power surges are of alternating length and Polarity transmitted, which represent the various signal symbols. Because of the very strong attenuation of the higher frequency characters on long transmission lines the short power surges are often attenuated so much that they disrupt the receiving line relay can not operate, even if long power surges arrive with such strength, that they can control the relays.

In order to enable signaling under such circumstances previously used synchronously operating pulse relay systems, consisting of relays, special Wrestling at the synchronous reception distributor and sometimes also from auxiliary equipment, such as Capacitors, passed. These cause the recovery in the receiving station the short power surges lost during transmission. Until now known systems have usually been with several polarized relays or with several Rings on the reception distributor or with two rings divided into segments (with special Isolation segments between the current-carrying segments of one ring). This was where the opposite contacts of some of the polarized relays were using Battery potentials of opposite polarities connected so that protective resistors in the battery lines had to be switched on to prevent short circuits due to wrong settings. If protective resistances in the battery lines If there were any, a special relay had to be arranged to avoid the power surges to transfer to a pressure distributor.

According to the present invention it is no longer necessary in one Impulse relay system more than two polarized relays and more than one smooth and to use a segmented ring on the receive distributor. Further it is no longer necessary in the system according to the invention, opposite To connect contacts of a relay with power sources of opposite polarity, which is why protective resistors in the battery cables are no longer necessary and a special one Pressure relay becomes superfluous. An embodiment of the invention is shown in the accompanying drawing.

Fig. I-shows-a-plant for the regeneration and printing of Signal surges received through a telegraph wire.

Fig. 2 shows curves that illustrate the operation of the system according to Fig. I represent.

Fig.3 shows a modified embodiment of the arrangement for the transmission the power surges on another line.

According to Fig. I, the pulse relay circuit includes a main pulse relay IVVR, an auxiliary pulse relay AVR, distribution rings VR and the circuit shown in solid lines. Both 1WVR and AVR are fast acting polarized relays, and each relay has two independent windings arranged such that a negative current from left to right moves the associated relay reed to the right, while a negative current from right to left moves the associated reed to the left leads. The two windings on the main pulse relay MVR work independently of each other. The upper winding LW is the line winding which, as shown, may be connected to the telegraph conductor, L, through an amplifier A, while the lower winding y W forms part of the pulse circuit. The operating current for the lower winding VW is kept at such a low value by the resistor 7 or the resistor 8 that the operation of the relay is controlled by the line winding Lfj whenever a signal circuit of several unit lengths is received via the line conductor L.

The resistors 3 and 4 are only arranged as contact protection and need not be discussed further here. The resistors 14 are also and i5, which are shunted to the windings of the relay AVR, only arranged to improve the working characteristics of this relay and do not need any further details here to be described.

The first step is to explain how the circuit shown in Fig. I works in conjunction with the curves in Fig. Z. The curves show the theoretical relationships. Curve 27 shows the shape of the wave sent from a remote station via line L, while curve z8 shows the shape of the current received after it has been amplified and applied to the line winding LW of the main pulse relay. In reality, the curves 27 and 28 are shifted relative to one another by an amount which is equal to the conduction time. This shift is not shown in the figure. As can be seen from the curves, a current of considerable magnitude is received when there are pulses of current which are longer than the unit length. Such power surges are z. B. present between a and d and between j and n. In the case of short current surges or current surges of unit length that are alternately of opposite polarity (such as between d and f, f and lt and h and j), only a very small current is received. The curves: 29 and 30 show the positions of the relay tongues of the main pulse relay MVR and the auxiliary pulse relay AVR for each instant. Plus values indicate that the tongue is against its right contact and minus values that it is against its left contact. The curve 3 i shows the current surges which are pressed onto the pressure magnets 22 to 26.

It is assumed that at time A a long positive current surge was sent over the line L, and that this current surge holds the main pulse relay MVR against its right contact (Fig. I). At the same moment brush 32 touches segment i and sends negative current from common ring 1g through resistor 3, upper winding 5 of auxiliary simpulsrelais A VR, contact 16 and relay reed 18 of MV R through earth to the positive battery. This creates a negative current that runs through the top winding of AVR from right to left, and tongue 13 is held against left contact io, as shown by curve 3o. At this point in time, no current flows through the tongue 13 and the pulse winding VW of MVR. At the time B, the brush 32 closes a circuit that runs from segment 2 through the resistor 4, the resistor 8, the winding VW and the contact io to the tongue 13 and to the positive pole of the battery. This creates a negative current that flows from runs through the winding VW from MVR on the left. The relay is not activated because, as indicated by curve 28, the line current in the line winding LW still controls the relay.

At the time point C, the relationships are the same as those of A, and a circuit is closed again, which generates a negative current, which to the left through the upper winding of the auxiliary simpulsrelais AVR, so that the tongue is held in the position it has already assumed.

At time D, brush 32 touches a segment again: 2 and sends negative current through segment q., Resistor q., Resistor 8, winding VW of the main pulse relay, contact io and tongue 13 of the auxiliary pulse relay to the positive pole of the battery. This creates a negative current which runs from right to left and leads the tongue i8 to the left because, as can be seen from curve 28, the current in the line winding has now assumed the zero value.

At the point in time E, the brush 32 again touches a segment i and presses a negative potential onto the center point of the auxiliary pulse relay AVR. Because the tongue 18 of iT b'R rests against contact 17, a negative current is created which runs from left to right through the lower winding of AVR, as a result of which the relay tongue 13 is guided against the right contact 12, as shown in curve 30 .

At the time F, when the brush 32 again touches a segment 2, a negative current is passed through the resistors q. and 7, the winding VW from 11llIhR, the conductor 12 and the tongue 13 of the auxiliary pulse relay fed to the positive pole of the battery. This negative current flows to the right through the winding VW of MVR and moves the tongue 18 to the right towards contact 16 because, as can be seen from curves 27 and 28, a current surge of unit length and negative polarity arriving from the remote transmitter is too small Current generated in the line winding LW by MVR in order to be able to control the action of this relay.

At time G, brush 32 again sends a negative current through segment i. The current runs to the left through the upper winding of the auxiliary pulse relay AVR and the contact 16 of the main pulse relay, 1.Ty'R, so that the tongue 13 is moved to the left (from curve 30). It should therefore be clear that as long as unit current surges of alternately opposite polarity are transmitted from the remote station, the line winding LW of the main pulse relay MTTR does not receive any current which can be used for control purposes. The relay system will therefore oscillate automatically and build up the unit current surges again. The processes described are repeated periodically up to the point in time L. At this point in time (curve 28) a current surge of more than a unit length is transmitted from the remote station, and a current of sufficient strength to be able to effect control flows through the line winding LW of the main pulse relay iI, IVR. Therefore, when brush 32 sends a negative current through segment 2, resistor 8, winding VW of MVR, contact io and tongue 13 of the auxiliary pulse relay, tongue 18 of the main pulse relay does not move to the left as it did at time D. (This is of course due to the control effect of the current in the line winding LW .) At the time lbl negative current still flows from right to left through the upper winding of the auxiliary pulse relay AVR, and the armature of the same is still against its left contact io.

At the time N, the current received in the winding LW of MVR has again assumed the zero value, and the negative current, which is sent through a segment 2, resistor 8, pulse winding VW, contact io and tongue 13 of the auxiliary pulse relay, moves tongue 18 against their left contact and causes the periodic oscillation of the armature to start again automatically.

Until now, the record has been received and regenerated Signals not described. In Fig. I there are pressure rings PR on the receiving distributor, which consists of the common ring 2o and a ring 35 divided into segments. Each segment of the ring 35 is connected to a pressure magnet. In the one shown here The system uses the Baudot code, which consists of five unit currents. Five pressure magnets 22 to 26 are provided for a current path. In a plant this Art can have any number of current paths, but there is the pressure equipment is the same for each current path, it is not necessary to have more than one current path to represent. The push magnets or relays 22-26 are of the commonly used type Kind, and each has a normal and a working position. The normal position corresponds to a negative and the working position to a positive signal current surge. When the relays are put into action, they are held in place until the brush 33 has passed all five segments in a current path and the given code character is printed. The relays are then automatically released and return back to the normal position. The common return conductor from the pressure magnets 22 to 26 in the first current path is connected to contact 16 of relay MVR, and the common pressure ring 20 is connected to the negative pole of the battery. The brush 33 moves in synchronism with the brush 32 and as shown by the curves in Fig. 2, the tongue of the main pulse relay MVR moves in synchronism with the transmitted ones Signals (curve 27). If so positive current surges from the remote Station are transmitted, the tongue of the main pulse relay is to the right, and when the brush 33 touches a pressure segment, a current is created that flows from the Negative pole of the battery via ring 2o, brush 3o through the pressure magnet to the contact 16 and positive pole of the battery connected to the tongue 18 runs. If at the time A positive rush current is transmitted; therefore the tongue 18 becomes the pressure magnet 22 notify an operating current surge. At the time point C, there is a positive rush current continuously transmitted from the remote station, and the print magnet 23 receives a power surge. At time E, a negative rush current is applied to the remote Station transmitted, and because the tongue 18 rests against the left contact, is an operating circuit for the pressure magnet 24 is not closed. This remains therefore in its normal position. At the point in time G, the remote station transmits a positive rush current, and tongue 18 of the main pulse relay pushes the push magnet 25 a power surge. At the time I, there is a negative rush current from the remote station sent; the tongue 18 is now against its left contact, and the pressure magnet 26 remains in its normal position.

As can be seen from the drawing, the common return line is for the pressure magnets (only four of which are shown) of the second current path not connected to contact 16 of relay MVR, but to contact 17. if there are more than two current paths, the common return conductor of each becomes second current path connected to the second next current path. The purpose of the connection of the return conductor from current path 2 (and from all current paths with even numbers) with contact 17 of relay i11bTR is to reverse the current surges that the pressure relay are pressed in these current paths. This is done for rectification too create for corresponding reversals of polarity in the transmitting station. Such Reversals, referred to as current path reversals, are used usually designed so that synchronizing surges can be transmitted, when there is no signal transmission.

In the system described above, there is a special pressure relay between the main pulse relay and the pressure rings of the distributor are superfluous. Such a thing However, the relay can be switched on if desired. A transfer relay can also be used can be used to transmit the regenerated current pulses to a second line. In Fig. 3, ARR denotes an auxiliary transformer relay, which is a two-winding relay is of the same type as the auxiliary pulse relay AVR. The two windings are connected in series, and the midpoint is to the negative battery connected, while the two terminals 36 and 37 with the contacts 16 and 17 of the main pulse relay 1bIVR. Because tongue 18 of the main pulse relay lI, IVR is connected to the positive terminal of the battery, a negative current will arise, that goes from right to left through the top winding of ARR, -if the tongue 18 of 1IIVR is against its left contact 17. The tongue 38 of ARR will therefore led against their left contact. But if the tongue 18 of the main pulse relay lies against their right contact 16, a negative current arises from the left runs through the lower winding of ARR to the right and tongue 38 to the right will lead. The tongue of the relay ARR thus follows the movements of the tongue of the main relay. If the opposite contacts of the auxiliary pressure relay ARR with the negative resp. connected to the positive battery post, as shown in Fig. 3, and the tongue 38 is connected to a second line ZZ, then received via the line L1 Current surges regenerated in the pulse relay system and sent out again via L.

Claims (6)

PATENT CLAIMS: i. Synchronous telegraph receiver for positive and negative direct current pulses, in which pulses of unit duration and of alternating polarity are generated locally by means of pulse relays which are connected to one another and controlled by a synchronized distributor to restore during the transmission of excessively damped pulses, characterized in that for Control of the pulse relays (HVR and AL R) only an uninterrupted distributor ring (1g), a divided distributor ring and a connecting brush (32) are used, and that the segments (1, 2) of the divided distributor ring alternately in the circuit of the working windings of one or the other of the other pulse relay (MVR, AVR). 2. Receiver according to claim i, characterized in that the Brush (32) that is moved over the segments, always the same polarity is placed over the full ring (ig). 3. Receiver according to claim i or 2, characterized characterized that the current from the segments through a winding (VW) of the pulse relay, depending on the position of the contact of the other relay, in one or the other Direction flows. q .. Receiver according to Claims i to 3, characterized in that the excitation circuit of each pulse relay winding, with the exception of the line winding, contains a distribution segment and a contact of the second pulse relay. recipient according to claim i, characterized in that the pressure magnets (2z etc.) have their working current obtained through the contact (18) of the main pulse relay (IITVR). 6. Recipient after Claim i, characterized in that a transmission relay (ARR) supplies its operating current through the moving contact (18) of the main vibration pulse relay (IlilV).